A Finite Element Formulation for Bending‐Torsion Coupled Vibration Analysis of Delaminated Beams under Combined Axial Load and End Moment

Composite wing design is complicated but inevitable to enlighten modern airplanes while maintaining the required performance. Using the dynamic transfer method, this paper discusses intensively the dynamic characteristics of a cantilever composite wing with both torsion and bending coupling to represent both material and geometric coupling. The governing differential equations are obtained based upon the principle of Hamilton and are solved analytically using a harmonic oscillation assumption. For this purpose, a MATLAB code is developed and results are validated in comparison with published work. Such a comparison shows a good agreement between both results. Finally, a parametric study is carried out to show the influence of the variation of both geometric coupling and torsion bending coupling rigidity on the free vibration analysis of the composite wing. The study shows the crucial effect of both factors on the dynamic behavior of the composite wing. The current research can be considered as a base for aeroelasticians while designing composite structures.

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The Second Stage of the Stress-Strain State of Reinforced Concrete Constructions under the Action of Torsion with Bending (Theory)

Kolchunov

Dem'yanov

Naumov

2020

IOP Conf. Ser.: Mater. Sci. Eng.

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Authors proposed a new approach for determining tangential torsional stresses for arbitrary cross sectional rods, based on simplified assumptions of material resistance. The main feature of this approach is the approximation of rectangular or any complex cross section of reinforced concrete structures by describing a large circle around the cross section and splitting it into small squares with circles inscribed into them. Authors have formulated three theorems. The first one relates the accumulation of tangential stresses (increments) from the edges to the middle of a rectangular cross-section with the formula for determining tangental stresses for round cross-sections. The second theorem allows us to establish a connection between the tangential stresses calculated for each of the small squares-circles and the tangent stresses of the large circle through their increments. The third theorem makes it possible to find tangential stresses for each of the small square circles. The proposed approach allows us to remove the need to use special tables for the calculation not only in the elastic stage. It also makes it possible to separate the stress-strain state in the whole set of round cross-sections from the additional field caused by the deplanation of the rectangular cross-section. In addition, the proposed approach makes it possible to take into account the concentration of angular deformations in the incoming angles and other places with changing geometric parameters.

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A Finite Element Formulation for Bending‐Torsion Coupled Vibration Analysis of Delaminated Beams under Combined Axial Load and End Moment

Cited by 6 publications

References 26 publications

Transient response of delaminated composite curved beams subjected to a moving force

Transient response of delaminated composite curved beams subjected to a moving force

Vibration analysis of composite wing with geometric and material coupling

The Second Stage of the Stress-Strain State of Reinforced Concrete Constructions under the Action of Torsion with Bending (Theory)

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